Quaternary substituted triazines

ABSTRACT

NEW QUATERNARY NITROGEN COMPOUNDS AND DYEING PROCESSES USING THESE QUATERNARY NITROGEN COMPOUNDS ARE PROVIDED. THE QUATERNARY NITROGEN COMPOUNDS MAY BE REPRESENTED BY THE FORMULA   B-((CH2)2-N(+)(-R1)(-R2)-R3)N (ANION(-))N   WHEREIN B REPRESENTS AN ACIDIFYING SUBSTITUENTS, RI, RII AND RIII EACH REPESENTS AN ALKYL RADICAL, OR ONE OF THEM REPSENTS AN NH2-GROUP WHILE THE REMAINING RADICALS ARE LINKED TOGETHER FORMING 5 AND 6-MEMBERED CYCLOALKYL RESIDUES, N IS A SMALL WHOLE NUMBER AND ANION$ REPRESENTS THE NEGATIVE RADICAL OF A MONOBASIC OR POLYBASIS ACID. THE DYEING PROCESSES PROVIDED ARE FOR THE COLORING OF FIBROUS MATERIALS WITH REACTIVE COMPOUNDS IN WHICH THE QUATERNARY NITROGEN COMPOUND IS EMPLOYED AS DYEING ASSISTANT TO PROMOTE THE REACTION BETWEEN THE REACTIVE COMPOUND AND THE FIBROUS MATERIAL.

United Smtes Patmt cc Int. Cl. C07d 55/14 US. Cl. 260-248 NS 3 Claims ABSTRACT OF THE DISCLOSURE New quaternary nitrogen compounds and dyeing processes using these quaternary nitrogen compounds are provided. The quaternary nitrogen compounds may be represented by the formula This application is a divisional application of Ser. No. 775,208, filed Nov. 12, 1968 which application is a continuation-in-part of our appliaction Ser. No. 317,138, filed Oct. 18, 1963, and now abandoned. It relates to new quaternary nitrogen compounds and dyeing processes using these compounds.

New quaternary nitrogen compounds have been found which have no dyestufl? character and which corresponds to the formula L Rm wherein B represents an acidifying substituent, R R and R each represents an alkyl radical, or R represents an NH -group and the remaining radicals represent alkyl radicals or are linked together forming 5 and 6-membered cycloalkyl residues, or all the radicals are linked together forming a bicyclic alkyl residue containing a tertiary nitrogen atom; n is a small whole number and anion represents the negative radical of a monobasic or polybasic acid.

The compounds of the Formula 1 have no dyestuff character and must therefore neither dye substrata nor have a true, distinct color of their own. In other respects, they are composed of the radical and n anions which latter, as shown in the formula 3,732,218 Patented May 8, 1973 may be linked only by an electrovalent bond with III or, as shown in the formula BCHgCl-l' N-R SO20 m in the case of the sulfonate ion, such an anion may be linked on the one hand by an electrovalent bond with and on the other by a covalent bond with B.

B in the Formula 1 represents an acidifying substituent which may be composed in a wide variety of ways; for example, it may be a carboxylic acid amide group linked through its carbon atom with Y. There are suitable monocarboxylic acid amide groups (that is to say in this case carboxylic acid amide groups derived from monocarboxylic acids and monoamines), where n=1, or dicarboxylic acid amide groups (derived from monocarboxylic acids and diarnines), where n==2. As an example of a dicarboxylic acid amide group there may be mentioned the group -C0--HNR NHOC- where R, is a bridge member, for example a phenylene group.

Also in the case of the monocarboxylic acid amides the amide nitrogen may be further substituted, for example by alkyl or hydroxyalkyl groups. Alternatively, an unsubstituted H N-OC- group may be concerned. A further acidifying substituent B is the nitrile group N=C, where n(=1.

Furthermore, B may be bound on the one hand to a ring nitrogen atom of a 1:3:5-trimethy1ene-triamine preferably the compound of the formula H: n in the latter case being 3, and on the other hand to CH CH Finally, B may be a sulphone group linked through the sulfur atom with --CH CH preferably an arylmonosulfone radical, such as a para-toluenesulfone radical, where 11:1.

The radical III in the Formula 1 is linked directly with the bridge member CH CH and the other respects satisfies the conditions stipulated above. The quaternary nitrogen radical may contain, for example, the radical of a tertiary amine or of a tertiary hydrazine.

The tertiary amines may belong to the aliphatic or heterocyclic series and correspond, for example, to the formula where R and R each represents an aliphatic radical with 1 to 4 carbon atoms, for example alkyl, hydroxyalkyl or alkoxyalkyl radicals; R represents an aliphatic radical 3 with 1 to 10 carbon atoms, for example an alkylene or alkyl radical, X represents a hydrogen atom, an unsubstituted or substituted hydroxyl group, the group the group (where 11:1, 2, 3 or 4), or a possibly substituted aryl radical; R R and R each represents an aliphatic radical with l to 4 carbon atoms, for example an alkylene radical, and Y stands for a nitrogen atom or a group.

In addition to one or more than one tertiary amine group the amines may contain further substituents, advantageously such as do not react with reactive dyestuffs under the conditions used in the dyeing process. As such substituents there are suitable halogen atoms, or nitro, alkoxy or hydroxyl groups. However, preferred use is made of amines that contain apart from at least one tertiary amino nitrogen atom only carbon and hydrogen atoms.

Suitablealiphatic amines of the Formula 5 are, for example, those of the formula where R has the above meaning and Z stands for a hydrogen atom or a hydroxyl group. Thus, these amines are such compounds as dimethylallylamine, dimethyl-fi-hydroxyethylamine or dimethyl-fl-ethoxyethylamine. Valuable results are also obtained with aliphatic amines of the H 0 ClIa Nalkylunc-N 113C CH3 (9) where the alkylene radical contains 1 to 10 carbon atoms, for example 1:2-bis-dimethylamino-ethane, 1:4 bis dimethylamino-butane or 1:6 bis dimethylamino-hexane. The most suitable aliphatic amines are those which correspond to the formula in which the alkyl radical contains 1 to 4 carbon atoms. Such compounds are, for example, dimethylethylamine, dimethylpropylamine, dimethylisopropylamine and above all trimethylamine.

As a rule, these aliphatic amines should not contain more than 6 carbon atoms per tertiary amino group. The term heterocyclic amines of the Formula 6 describes tertiary amines in which the nitrogen atom, or both nitrogen atoms, belongs or belong at the same time to several rings so that the nitrogen atom of the tertiary amino group(s) forms a bridge member between several rings. These rings may contain substituents such as halogen atoms, or nitro, hydroxyl, keto or alkoxy groups; they may also be fused together with other rings or ring systems which themselves may likewise contain substituents. Preferred use is made of heterocyclic amines that contain only carbon and hydrogen atoms apart from the tertiary amino group(s). It has also proved advantageous when no more than 8 carbon atoms per tertiary amino group are present. Suitable representatives of this group are, for example, amines of the formula Hz? (EH2 CH2 1120 I12 132 which may also be represented by the following simplified formula When the quaternary nitrogen compounds of the Formula I belong to the hydrazine series, they must likewise contain at least one tertiary nitrogen atom, that is to say that one of the two nitrogen atoms of such a hydrazine grouping must be linked as a tertiary nitrogen atom with two carbon atoms, whereas the other nitrogen atom may be substituted or unsubstituted. Further suitable are cyclic hydrazine compounds, more especially those in which one of the two hydrazine nitrogen atoms or both form a member of one or more than one ring.

In general, it is advantageous to use hydrazines that are soluble in the dyebath or printing paste. In addition to one or more than one hydrazine group they may contain substituents that do not react with the reactive dyestuffs, for example halogen atoms, or nitro, alkoxy or hydroxyl groups. It is, however, preferable to use hydrazines that contain only carbon and hydrogen atoms apart from at least one NN group, for example hydrazines that contain at least one tertiary nitrogen atom and are substituted by non-aromatic hydrocarbon radicals.

Such hydrazines may correspond, for example, to the formula where R and R each represents an aliphatic hydrocarbon radical with up to 4 carbon atoms, and R represents likewise such a radical or an HS-CS- group, an HO S-group, an

The purely aliphatic hydrazines of the Formula 14 correspond with advantage to the formula (16) (Cm Zm-H) n-l v-l) f (Gilliam) H where m and n each=i1, 2, 3 or 4, preferably=l and p: 1, 2, 3, 4 or 5. The aliphatic hydrocarbon radicals in these hydrazine compounds may be branched, but preferably they are linear.

Finally, there may also be mentioned especially those hydrazine compounds in which the vicinal nitrogen atoms at the same time form members of two fused rings, for example those of the formula Where r and s may be identical or different and each represents 3 or 4.

Specifically, there may be mentioned as examples the following hydrazines:

NzN-dimethylhydrazine, NrN-methylethylhydrazine, N-aminopyrrolidine of the formula (17a) CH2-CH2 N-NH CHz-Cz N-aminopiperidine of the formula (18) OHt-C'Ha H2 N-NH OHQ'CIIQ 1:5'diazabicyclo(0:3:3)octane of the formula (19) CH2 CH2 N CH\2 OH: 062 \OH2 alkyl l-I alkyl $0311 30 soaH alkyl S N-NlI-iL-SII alkyl The anion may be the negative radical of a monobasic or of a polybasic, preferably inorganic, acid. As most important radicals of this kind there may be mentioned above all halogen preferably Cl SO H or PO H because of their ready accessibility, but this, of course, does not exclude other appropriate radicals.

The quaternary nitrogen compounds of the Formula 1 can be manufactured by reacting a tertiary nitrogen com pound in the molecular ratio of lzn with halogen compounds of the formula (24) B (CH cH -halogen) or with esters of the formula (24a) B (CH CH O-R n where B and n have the above meanings and R represents the radical of a polybasic inorganic acid. The quaternization may take place by way of an additive reaction, when the tertiary nitrogen compound is reacted with a heterocyclic compound that contains at least one mobile halogen atom and is free from acid substituents capable of forming anions, such as carboxylic acid or sulphonic acid groups. When, on the other hand, a tertiary nitrogen compound is reacted, for example, with a compound of the formula (25) B-C H2 CHz-halogen S O Me where B and Y have the above meanings and Me represents a cation, preferably an alkali metal ion--MeCl is eliminated and a quaternary nitrogen compound of the formula B --C H2 C 112-1 1-431 S O2O m is formed, where B, Y and R have the above meanings. Quaternary compounds of the Formula 1 that contain an NzN-dialkylhydrazine radical linked with Y are also obtained by reacting a suitable tertiary nitrogen base with chloroamine.

The new quaternary compounds of the Formula 1 are advantageously used as assistants in coloring, i.e. dyeing and printing fibrous materials with reactive compounds suitable for dyeing purposes i.e. reactive dyestuffs or reactive dyestuff intermediates, using as an agent capable of promoting the reaction between the dyestuff and the substratum a quaternary nitrogen compound that has no dyestuff character and corresponds to the above Formula 1. Promotion of the reaction between dyestuff and substratum means also a stabilisation, that is to say delaying of the hydrolysis, of reactive dyestuffs which in aqueous preparations substantially exchange the reactive grouping for an unreactive hydroxyl group before the former can enter the desired covalent bond with the substratum.

As generally applied, the term reactive dyestuffs describes dyestuffs that enter a covalent bond with the material to be dyed during the dyeing or printing process; as a rule, this is accompanied by the splitting off of the reactive substituent of the dyestuff. The speed at which the bond between dyestuff and substratum is formed depends on one hand on the dyeing conditionssuch as temperature, pH value of the dyebath or of the printing pasteand on the other on the reactivity of the reactive grouping of the dyestuff. It is known that in this respect there exist considerable differences between individual reactive dyestuffs. With the aid of the quaternary nitrogen compounds of the Formula 1 it is now possible to increase considerablly the reactivity of these dyestuffs.

It is of advantage to use in the present process Watersoluble reactive dyestuffs, for example organic dyestuffs containing carboxyl groups, sulfonic acid groups or aliphatically bound sulfuric acid ester groups. As relevant reactive groupings there may be mentioned the epoxy groups, ethyleneimino, isocyanate, isothiocyanate, carbamic acid aryl ester groups, the propiolie acid amide grouping, monoand dichlorocrotonyl amino groups, chloroacrylamino, acrylamino and vinylsulfone groups and above all groupings that contain an exchangeable substituent and are easy to split with removal of the bond electron pair, for example sulfonyl halide groups, aliphatically bound sulfuric acid ester groups and aliphatically bound sulfonyloxy groups, and halogen atoms, more especially an aliphatically bound chlorine atom. Advantageously, these exchangeable substituents are in position 7 and ,3 of an aliphatic radical which is bound to the dyestuff molecule directly or through an amino, sulfone or sulfonamide group. In the case of these relevant dyestuffs which contain as labile substituents halogen atoms, these 8 exchangeable halogen atoms may also be present in an quinone-Z-sulfonic acid and the dyestuffs derived from aliphatic acyl radical, for example in an acetyl radical, 1:4-diaminoanthraquinone-Z-sulfonic acid. These and or in B'P or and hP of a p y radi" other anthraquinone dyestuffs are manufactured in the 6310f Preferably in a heterocycle for example in apyrhhi' usual manner. As suitable phthalocyanine dyestuffs there (line or pyhdahihe ring, or above an ih ahiazihe rihg- The 5 may be specially mentioned those which are derived from dyestuffs contain advantageously a grouping of the formula nickel or copper phthalocyanine sulfonamides Whose N N molecule contains at least two free sulfonic acids and \c halogen which contain in at least one sulfonamide radical a group I 1] or comprising at least one labile halogen atom. Further suitable are phthalocyanines containing as solubilizing, and at the same time reactive, substituents aliphatically bound halogen halogen acid sulfuric acid ester groups, for example one of the (2 formula Where X represents a nitrogen bridge and Z a hydroand may contain as further solubilizing groups sulfonic gen atom, a possibly substituted amino group, an etheriacid p Such dyestuffs are manufactured in the fied hydroxyl or mercapto group, a halogen atom, or an known manner.

alkyl, aryl or aralkyl group, and A represents a hydrogen The present process may also be performed by using or halogen atom, The halogen atoms are, for example, vat dyestuffs that are water-soluble or insoluble also in the b o in or preferably fluo i t oxidized form and dispersion dyestuffs having the charac- Particularly valuable are dyestuffs that contain the ter of reactive dyestuffs.

grouping of the formula There are several advantageous variants for the performance of the present process. Thus it is possible to use (28) CnHhH different proportions, for example for every reactive group 30 of 1 molecular proportion of dyestuff at least 1 molecular g z proportion of the quaternary nitrogen compound, or for 1 'l an identical amount of dyestuff less than 1 molecular proportion of the quaternary nitrogen compound. For either ratio there may be used the following two methods: 01 (a) The fibrous material is dyed or printed with a prep- Where 3 0F and Z has the above meaning aration consisting of the reactive dyestuff and the qua- It is also possible to use dyestuffs that contain dipheternary nitrogen compound; noxytriazine groupings as well as those which contain a (b) Th ti dyestuff and the quaternary nitrogen grouping of the formula 40 compound are applied separately to the fibrous ma- (29) X material.

The variant (a) is suitable not only for a stoichiomet- N ric ratio but especially well also for a ratio in which for every reactive group of 1 mole of dyestuff less than 1 mol of the quaternary nitrogen compound of the Formula 1 is whcrcxstands for used; it is especially suitable for a catalytic ratio which,

as generally understood, means a who that is substantially below the aforementioned stoichiometric ratio. The =CIl--, 0- amount of quaternary compound referred to the reactive Or=N andY1.ePl.eSentsa 5O dyestuff may, however, vary within certain limits. Re-

ferred to the weight of the dyestutf, the catalytic amount lf of the quaternary compound may be about 0.1 to 10% S by weight and preferably about 0.2 to 2% by Weight. Ora When performing the variant (b)using the quater- N nary compound likewise in a stoichiometric or catalytic proportion-the reactive dyestuff and the quaternary compound are applied to the fibrous material in either order s of succession, if desired interposing an intermediate drygroup, where R stands for an ortho-aryl radical. mg Operahoh- Further suitable reactive groupings are the following In other respects It m y be left 1 Whether and to radicals: Trichloropyridazine,dichloroquinoxaline,dichlo- What extent the reachoh hetweeh the reilctlve yestufi robutene, halogenated pyridazone; sulfonyl-dichloroproh the qhalierhavry colhpohhd by elther vaflant a n the pylamide, allylsulfide, 2-halogeno-benzthiazolecarbamide, (hfiel'eht rahos gives use to other Teactlons, Such as splitisothiocyanate and pl-sulfatopropionamide radicals. hhg of thehhaterhary compohhd of the Formula 1 and A very wide variety of organic dyestuffs may be used in any formahoh of quaternary hltrogen Compounds f the the performance of the present process, for example oxareachve dyesthhszine, triphenylmethane, xanthene, nitro, acridone, azo, What h sald above regardlngfhe l edyeanthraquinone and phthalocyanine dyestuffs stuffs applies similarly also to the reactive dyestuff inter- From among the am d t ff thgre may be mentioned mediates, for example reactive coupling components. as examples disazo and trisazo dyestuffs, and above all The h Process may h used for r ng,i. dyemonoazo dyestuffs. A large number of such reactive azo 1 g a d Prlnllng, a large varlety 0f fibr 8 mat rials such an identical amount of dyestuff less than 1 molecular proas P p or leather, above all textiles, example those them here i greater il consisting of animal fibers such as silk and especially of From the series of the anthraquinone dyestuffs there cellulosic fibers such as linen or cotton, and also fibers may be mentioned especially l-amino-4-bromoanthraof regenerated cellulose such as rayon (viscose rayon) or spun rayon. Quite generally, dyeing and printingmore especially also when a catalytic proportion of the quaterary compound is used-follow the dyeing and printing practice usual for'reactive dyestuffs. For dyeing and printing cellulosic textile materials it is of special advantage to use concomitantly an inorganic acid acceptor such as a carbonate, hydroxide, bicarbonate or phosphate of an alkali metal or a mixture thereof, and also bases such as trimethyl benzyl ammonium hydroxide or sodium trichloroacetate. In conjunction with reactive vat dyestuffs there may be used the conventional reducing agents such as sodium hydrosulfite, thiourea dioxide, sodium sulfide or sodium sulfoxylate. When, however, a quaternary com pound of the Formula 1 is used, it is possible to fix reactive vat dyestufs on the fiber even in the absence of the afore-mentioned reducing agents.

Other substances conventionally added to dyebaths and printing pastes such as electrolytes, for example sodium chloride or acetate, or non-electrolytes such as urea, or thickening agents such as alginates, may likewise be used. To prevent any undesired reduction, more especially in the case of delicate dyestuffs, one of the conventional additives, such as meta-nitrobenzenesulfonic acid, may be employed. As a rule the quaternary compound is incorporated with the dyebath or with the printing paste. When a two-stage dyeing method is used, the application of the dyestuif and the fixation with the acid acceptor being performed separately, the quaternary compound may alternatively be added in the second stage.

As mentioned above the fibrous materials are dyed or printed under the conditions generally used for working with reactive dyestuffs. The present process allows the reaction times and/ or reaction temperatures to be reduced and/ or to produce more intensive dyeings and prints, for example in the cold pad batch method, in the exhaustion method, in the pad steam and pad dry methods, in the pad wet steam method and in printing. Depending on the method selected the dyestuffs may be fixed within a wide temperature range, for example from to 200 C., or above it, for example at 250 to 300 C.

Unless otherwise indicated, parts and percentages in the following examples are by weight. The dyestuffs are as a rule shown in the form of the free acids but they are actually used in the form of the alkali metal salts thereof.

EXAMPLE 1 A solution of 12 parts of the compound of the formula in 50 parts by volume of dimethylformamide is mixed with 6 parts of NzN-dimethylhydrazine.

The batch is left to itself for several hours at room temperature. The precipitate formed is filtered off, and washed with dimethylformamide and dioxane. The resulting, highly hygroscopic product of the probable formula is dried at room temperature under vacuum.

is obtained by using instead of N :N-dimethylhydrazine an equivalent amount of 1:4-diaza(2:2:2)bicyclooctane in the method of Example 1.

EXAMPLE 3 A solution of 12 parts of l:4-diaza(2:2:2)-bicyclooctane in parts by volume of dimethylformamide is mixed with 9 parts of fi-chloropropionitrile and then left to itself for several hours at room temperature. The precipitated crystals are filtered off, and washed with a small amount of dimethylformamide and then with 100 parts by volume of acetone. The resulting product of the formula NEC-OH2CH2N N] 01 is dried under vacuum.

EXAMPLE 4 A mixture of 6 parts of NzN-dimethylhydrazine, 100 parts by volume of dimethylformamide and 9 parts 0f 5- chloropropionitrile is kept for seVeral hours at room temperature, then heated to 50 C., mixed with 200 parts by volume of dioxane and cooled to 20 C. After 4 hours the precipitated product of the formula NEG-OHzGHz-N-NHz] 01 is filtered ofr, washed with 100 parts by volume of dioxane and dried under vacuum.

In an analogous manner the compounds of the formulae (104a) 0113 G9 I H2N1TICH2-OH2-OOO6 N C 2 CH2 COO are prepared, using as starting materials B-propiolactone and N:N-dimethylhydrazine, or fi-propiolactone and 1:4- draza 2 2 2) bicyclooctane.

EXAMPLE 5 A solution of 11 parts of the compound of the formula i n 50 parts by volume of dimethylformamide is mixed with a solution of 6 parts of l:4-diaza(2:2:2)bicyclooctane in 30 parts by volume of dimethylformamide, and the reaction mixture is left to itself for several hours at room temperature. The precipitated product of the formula is then filtered off, washed with acetone and dried under vacuum.

The compound of the formula e N] sour is manufactured in a similar manner, using as starting materials the sodium salt of the compound of the formula HaC S Og-CIIT-CI'IZ-O- S O OH and l:4-diaza(2:2:2)bicyclooctane.

EXAMPLE 6 A solution of 22 parts of the compound of the formula 1130- S Oz-CHzCIh-Cl in 100 parts by volume of dimethylformamide is mixed with 6 parts of NzN-dimethylhydrazine. The reaction mixture is kept for to 10 hours at room temperature and mixed with 500 parts by volume of dioxane while being agitated. After another 3 hours the precipitated product of the formula e l IhC-O-SOz-ClIzCHz-III-Nlh] 01 is filtered off, washed with dioxane and dried under vacuum.

In an analogous manner the compounds of the formulae are manufactured, using as starting materials [i-chloropropionic acid methyl ester and NzN-dimethylhydrazlne, or N-aminopyrolidine respectively, or N-aminopiperidine.

EXAMPLE 7 A solution of 100 parts by volume of dimethylformamide, 11 parts of ,B-chloropropionic acid amide and 12 parts of 1:4-diaza(2:2:2)bicyclooctane is kept for 3 days at to C. The precipitated product of the formula is then filtered off, washed with dioxane and dried under vacuum.

EXAMPLE 8 The product of the formula (10s) cm a) 11=N-oo-ouomN-N1n:l 01

is prepared as described in Example 7, replacing 1:4- diaza(2:2:2)bicyclooctane by an equivalent proportion of NzN-dimethylhydrazine.

EXAMPLE 9 A solution of 40 parts of the dyestulf of the formula (201) 0 NH, 1 -s031r 01 o /N o T 3H III/ 5 all 0 llN-O-Nl-I-U O-lIN- in 700 parts of boiling water is cooled to 20 C. and then mixed with 10 parts by volume of sodium hydroxide solution of strength, 20 parts of crystalline sodium 12 sulfate, and 0.1 part to 1 part of the compound of the formula (1011)). The resulting solution is made up with cold water to a volume of 1000 parts.

This solution is used to pad a cotton fabric to a Weight increase of which is immediately thereupon rolled up and kept in this rolled-up state for 6 to 12 hours at 20 C. After this storing the unfixed portion of dyestuff is removed by a good rinse in cold and in boiling water, and the dyeing is finally soaped in the usual manner.

The resulting blue dyeing has good fastness to light and washing which is much stronger than a comparable dyeing obtained in the absence of the quaternary compound.

Good results are also obtained when 15 parts of trisodium phosphate instead of 10 parts by volume of sodium hydroxide solution are used.

Similar results are obtained when the abovementioned compound of the Formula 10lb is replaced by the compound of the Formula 102, 104a, 104b or 106.

EXAMPLE 10 A cotton fabric is impregnated at 50 C. with a padding solution containing per 1000 parts of water 30 parts of the dyestul'f of the formula and then dried. The fabric is then padded with a solution containing per 1000 parts of water 200 parts of calcinated sodium sulfate, 10 parts by volume of sodium hydroxide solution of 30% strength and 0.2 to 5 parts of the compound of the Formula 107. The fabric is rolled up, stored for 3 to 6 hours at room temperature and then finished off as described in Example 1.

The resulting brilliant red dyeing is distinctly stronger than a comparable dyeing produced without adding the compound of the Formula 107.

When the compound of the Formula 107 is replaced by the quaternary compound of the Formula 108, and instead of sodium hydroxide 20 parts of sodium carbonate, stronger dyeings are likewise obtained than when this additive is not present.

Equally good results are obtained on viscose rayon fabrics or spun rayon fabrics.

in 250 parts of boiling water is added to a dyebath containing per 750 parts of water 60 parts of sodium chloride. 50 parts of cotton yarn are dyed in the resulting dyebath for 30 minutes at 40 C. The fixation of the dyestuff deposited on the fiber follows upon this exhaustion operation in the same dyebath, adding 15 parts of trisodium phosphate and 0.5 part of the compound of the Formula 102. The fixation takes 1 /2 hours at 40 C. The dyed yarn is thoroughly rinsed in cold and in hot water and finally soaped at the boil.

A brilliant violet dyeing is obtained which has good fastness properties and is of much greater tincton'al strength than a dyeing produced in the absence of the triquaternary ammonium compound.

When the dyestutf used above is replaced by an equivalent amount of the dyestuff of the formula water to 1000 parts by volume.

A cotton fabric is impregnated on a padder with the (204) C1 above solution to a weight increase of 70%, then rolled up I and stored for 6 hours at a constant temperature of 25 5031; 10 C. After this storing the material is given a good rinse N N l in cold and in hot water and finally soaped at the boil. H035 0 Cu 0 A brilliant yellowish green dyeing is obtained. A coml l s parable combination dyeing produced in the absence of N the quaternary ammonium compound is of lesser tinctorial strength. H033 SQ3H EXAMPLE 13 By using instead of the dyestuffs defined in Example 12 S0311 a combination of 30 parts of the dyestuff of the formula good results are likewise obtained. (208) P (SO3H)3 Similarly good results are also obtained when 2 parts (3) SO2-NH SOaH of the quaternary compound of the Formula 103 are used.

Distinct effects are also obtained by using the dyestuif I of the formula C I/ (205) H21]: f 0 01-0 J-HN- sour H033 N N 50311 01 01 (Cu-Pc=copperphthalocyanine radical) H0 HN-Ci EN and 20 parts of the dyestufi of the formula /ON S03H which is obtained by condensing the copper complex of N=N-O the aminoazo dyestuif with tetrachloropyrimidine in an CZN aqueous medium at a pH ranging from 6 to 9. 40 HOsSOCH2-OHz-S0z H l 3 EXAMPLE 12 in the identical dyeing method, a brilliant green dyeing is 30 parts of the djyestuff of the formula obtained which has similar, good properties.

By using 20 parts of the 1:2-cobalt complex of the dye- (206) (S03H)2 Stuff Of the formula --SO2NH2 C1 C1 S02NH (210 HO 0H N C P (3) HN-O N O N=NC (CuPC:copperphthalocynnlne radical) zNH H2CH2 2- 1 and 20 parts of the dyestufi of the formula ,5 as yellow component, an olive shade is produced.

t) CH (207) (I31 3 EXAMPLE 14 SOBH 01 A cellulose fabric is padded at 20 to 30 C. with a so- E lution containing per 1000 parts of water 20 parts by vol- O=O-N=N 503K ume of sodium hydroxide solution of 30% strength, 20 H03 5 H parts of sodium sulfide and 20 parts of the dyestuff of the HNC CHN- formula 01 31 (I) I I HzN-t l b-NH O HNC\ /CNH2 M are together dissolved in 800 parts of boiling water; the solution is cooled to 25 (3., mixed with 16 parts of trisodium phosphate, 8 parts by volume of sodium hydroxide solution of 30% strength and 2.5 parts of the compound of the Formula 102, and the whole is made up with cold as well as 8 parts of the compound of the Formula 103 or ties of fastness and is likewise much stronger than a 105b, then rolled up, wrapped in a plastic foil and left comparable dyeing produced in the absence of the comto itself for 12 hours, then rinsed, oxidized, soaped at the pound of the Formula 104.

boil, once more rinsed and then dried. A vivid red dyeing results which is fast to washing at the boil. EXAMPLE 17 EXAMPLE A cotton fabric is padded at 40 C. with a solution con- A solution of 0.6 part of the dyestuif of the Formula taining in 1000 parts of Water 30 parts of the dyestuff 202 used in Example 9 in 100 parts of hot Water is added of the formula to a dyebath containing in 900 parts of water 50 parts of sodium chloride. parts of real silk are dyed in this 10 (214) -(SOaH)M dyebath for minutes at C. The dyestulf which has O deposited only in substance on the fiber is fixed by adding (s 2 N 0011201) 2 parts of sodium carbonate and 0.5 part of the com- 0f copperphthalocyahlhe) pound of the Formula 104 for 90 minutes at 40 C., then 60 Parts Of urea, 20 Parts Of Sodium carhonatfi and 3 Parts thoroughly rinsed in cold and hot water and finally soaped 0f the compound of the Formula 1 then dried at 60 10 at 70 C. 80 C. and steamed for 30 seconds. The steamed fabric is The resulting brilliant red dyeing is fast to light and rinsed in cold and hot water and soaped at the boil. washing and considerably stronger than a comparable The resulting turquoise dyeing has good properties of dyeing produced without adding the quaternary comfastness. pound. 20 A dyeing obtained by the identical method but without When the dyestuff used above is replaced by an equivaddition of the compound of the Formula 107 was of alent proportion of the disazo dyestulf of the formula substantially lesser tinctorial strength.

N-C HOaSON=N-N=N NH-C /N l N: H03 i NH SIOZH Hogs a yellowish brown dyeing is obtained. EXAMPLE 18 EXAMPLE 16 40 A printing paste is prepared from the following ingre- A solution of 40 parts of the coupling component of dlents: the formula parts of the dyestuif of the Formula 202 of Example 10,

parts Of urea, r 378 parts of water, 350 parts of sodium alginate thickening 5011000, 10 parts of sodium bicarbonate, 2 parts of the compound of the Formula 10 lb and E IL SOSH 10 parts of sodium meta-n1trobenzenesulfonate,

50 and printed on a cotton fabric on a roller printing ma- 01 chine; the fabric is then dried and steamed for 1 minute on a Mather Platt ager at 100 C. The fixed print is rinsed 110 H in cold and hot water and then dried. A red, level print is in 928.6 parts of water is mixed with 10 parts of sodium Pbtained of the m tincforial Strength as when fixing hydroxide solution of 30% strength, 20 parts of crystal- 1s Performed for 8 mmutes In the absence 0f the OOIDPOUHd line sodium sulfate and 1.4 parts of the compound of the of the F9rm111a l Form l 104, A similar result 15 obtained on spun rayon fabric.

A mercerized cotton fabric is impregnated with this Similar effects are Obtained by using 5 P of the solution on a padder, rolled up and stored for 3 hours at quaternary Compound of the Formula 105b, 1053, 10% a constant temperature of 30 C., whereupon the unfixed 105cportion of dyestulf is Washed out by a good rinse in cold EXAMPLE 19 and hot water. t

The fabric impregnated in this manner is than diegtsprmtmg pas e 15 prepared from the following ingreveloped with a freshly prepared solution containing per 1000 parts of water 2 parts of the diazo compound of 50 parts of the dyestutf of the formula metachloraniline, then coupled, rinsed and soaped at the (215) boil. The brillilant scarlet shade thus obtained has good 01 fastness to washing and rubbing.

A comparable dyeing produced in the absence of the H038 N sotH afore-mentioned quaternary ammonium compound is sub- H 01 stantially Weaker. 6

When the development is performed wlth 2 parts (per HNC N 1000 parts of water) of diazotized I-amino-Z-methoxy- S-nitrobenzene instead of with meta-chloraniline, a deep claret dyeing is obtained which has good general properl 17 [obtained by condensing the aminoazo dyestuif with 2 4: fi-trichloropyrimidine] 100 parts of urea, 420 parts of water, 400 parts of sodium alginate thickening 50: 1000, 10 parts of sodium bicarbonate. 10 parts of the compound of the Formula 1005b and 10 parts of sodium meta-nitrobenzenesulfonate,

and printed on a cotton fabric on a roller printing machine or by the screen printing .method. The fabric is then dried, fixed for 30 seconds in a rapid ager and finished 01f as described in Example 8. The resulting yellow print is of greater tinctorial strength than when the compound of the Formula 105b is omitted.

Similar results are obtained by using the compound of the Formula 107 instead of the compound of the Formula l05b.

EXAMPLE 20 A printing paste is prepared from the following ingredients:

50 parts of the dyestuff of the formula (216) (-SOaH)2.5

(Cu-Pc-=radical of copperphthalocyanine) 400 parts of water and 550 parts of sodium alginate thickening 50:1000 and printed on a cotton fabric which is then dried and impregnated on a padder with a solution containing in 1000 parts of water 150 parts of sodium chloride, 100 parts of potassium carbonate, 30 parts by volume of sodium hydroxide solution of 30% strength and parts of the compound of the Formula 107, then squeezed to a weight increase of 70% and, without intemnediate drying, rfixed for 30 seconds in a rapid ager. The fabric is then finished off as described in Example 8.

The resulting turquoise print is of substantially greater tinctorial strength than when the abovementioned quaternary ammonium compound is omitted.

A similarly good eifect is achieved on spun rayon fabric.

Alternatively, the quaternary compound of the Formula 107 may be incorporated directly with the printing paste.

EXAMPLE 21 A printing paste is prepared from the following ingreclients:

50 parts of the dyestuff of the Formula 208,

200 parts of urea,

320 parts of water,

350 part sof sodium alginate thickening 50:1000,

60 parts of aqueous potassium carbonate solution of 50% strength,

1.0 parts of the compound of the Formula 107 and 10 parts of sodium meta-nitrobenzenesulfonate and printed on a cottom fabric on a roller printing machine. The fabric is dried and then fixed for 30 seconds in a rapid ager and finished off as described in Example 15.

The resulting turquoise print is of considerably greater tinctorial strength than when the dyed fabric is fixed for 8 minutes without the compound of the Formula 118 first having been added.

Instead of the compound of the Formula 107 there may be used an equivalent proportion of the compound of the Formula 102 and 103.

18 An equal result is obtained when the dyestulf of the Formula 208 is replaced by the dyestuff of the Formula 206.

EXAMPLE 22 A printing paste is prepared from the following ingredients:

50 parts of the dyestufl of the Formula 202 used in Example 9.

200 parts of urea,

375 parts of water,

350 parts of sodium alginate thickening 50:1000,

10 parts of sodium bicarbonate,

5 parts of the compound of the Formula 101b and 10 parts of sodium meta-nitrobenzenesulfonate and printed on a cotton fabric on a roller printing machine, then dried and stored for 24 hours at 35 to 40 C. and finished off in the known manner. A red print is obtained. A substantially weaker shade is obtained when the quaternary compound is omitted.

An equal effect is obtained when the printed fabric is stored at a lower temperature (20 to 30 C.) for 2 to 3 days, whereas at a higher temperature (60 to C.) a comparable effect is achieved within 30 to 60 minutes.

EXAMPLE 23 A mercerized cotton fabric is padded at 30 C. with a liquor containing in 1000 parts of water 30 parts of the dyestuff of the formula EXAMPLE 24- 30 parts of the dyestuff of the Formula 202 mentioned in Example 10 are mixed with 50 parts of urea and dissolved in 700 parts of boiling water. This solution is cooled to 40 C., mixed with 20 parts of sodium carbonate and 2 to 10 parts of the compound of the Formula 105b, and the whole is made up with cold water to 1000 parts.

A cotton fabric is impregnated with this solution on a padder to a weight increase of 75%, then directly, that is to say without intermediate drying, steamed for 1 minute and finally rinsed and soaped in the usual manner.

The resulting brilliant red dyeing displays very good fastness to light and washing. When dyeing as described above but in the absence of the compound of the Formula 105b, a substantially weaker dyeing results.

Advantageous effects are also achieved when the dyeing, before the steaming operation, is stored for 30 to 60 minutes in the wet, rolled-up state (to prevent partial drying).

19 20 EXAMPLE 25 I wherein R and R are defined as above, (4) A solution of parts of the dyestulf of the formula t\ N (21s or OH s 03H (i) 5 ii/n $0311 N=N- wherein R R and X are defined as above and n is an I N integer from 1 to 4; R R and R are each alkylene L g 50111 having 1 to 4 carbon atoms and Y is a nitrogen atom or a 10 I in 250 parts of boiling Water is added to a dyebath con- -0 taining per 750 parts of water 60 parts of sodium chloride. 1 50 parts of cotton yarn are dyed in the resulting dyegroup; and a hydrazine of the formulae bath for 30 minutes at 40 *C. The fixation of the dyestuff R13 (0H,) deposited on the fiber follows upon this exhaustion opd N 1 eration in the same dyebath adding 15 parts of trisodium 7 phosphate and 0.5 part of the compound of the Formula 12 H 2) 101b. The fixation takes 1% hours at 40 C. The dyed wh rein R and R are each alkyl having 1 to 4 carbon yarn is thoroughly rinsed in cold and in hot Water and atoms; R i hydro n, alkyl having 1 t 5 bon finally soaped at the boil. t th A brilliant orange dyeing is obtained which has good fastness properties and is of much greater tinctorial ll strength than a dyeing produced in the absence of the HS gmul triquaternary ammonium compound. the SO H group, the

We claim: R 1. A compound of the formula \NalkYlcne COCHzCHzR 6) R12 1 group wherein R and R are each lower alkyl having I e 1 to 4 carbon atoms and R and R taken together anion 1,,

form a 5- or 6-membered ring; and r and s each rep- RH1OH2COC N N COCHZOH2R resents the integer 3 or 4.

n 2. The quaternary nitrogen compound of the formula CH 63699 in which n is a small whole number, anron IS the nega- I a tive radical of a monobasic or polybasic acid, all R groups E I are the same and R is a member selected from the group N 0113 consisting of the following formulae 6,

R4 40 HgNl ICIIzClIzCO-l I r r-co-onz-onz-r r-Nrrz 301 N-R -X and N Ri;Y CH3 CH2 (3H3 R1 R5 3. The quaternary nitrogen compound of the formula CO-ClIz-CHz-N \N @696) N /ClizGHg (IJIIZ N-CHz-CHz-NClIz-OIIz-CO-N NC0-Cll'zOlI1-N N 301 CHz-CH CH1 wherein R and R are each alkyl, hydroxyalkyl or alkoxy- References Cited alkyl having 1 to 4 carbon atoms; R is alkylene or UNITED STATES PATENTS alkenylene having 1 to 10 carbon atoms; X is (1) hydrogen, (2) hydroxy, (3) 3,539,547 11/1970 Hoffman 260248 R1 JOHN M. FORD, Primary Examiner -N US. Cl. X.R.

R1 260--268 BC, 465.5 R, 570.5 P, 326.3, 567.6 R 

